Incommensurate heterostructures in momentum space

Daniel Massatt; Stephen Carr; Mitchell Luskin; Christoph Ortner

doi:10.1137/17M1141035

Incommensurate heterostructures in momentum space

Daniel Massatt
, Stephen Carr
, Mitchell Luskin
, Christoph Ortner

Research output: Contribution to journal › Article › peer-review

23 Scopus citations

Abstract

To make the investigation of electronic structure of incommensurate heterostructures computationally tractable, effective alternatives to Bloch theory must be developed. In [Multiscale Model. Simul., 15(2017), pp. 476-499] we developed and analyzed a real space scheme that exploits spatial ergodicity and near-sightedness. In the present work, we present an analogous scheme formulated in momentum space, which we prove has significant computational advantages in specific incommensurate systems of physical interest, e.g., bilayers of a specified class of materials with small rotation angles. We use our theoretical analysis to obtain estimates for improved rates of convergence with respect to total CPU time for our momentum space method that are confirmed in computational experiments.

Original language	English (US)
Pages (from-to)	429-451
Number of pages	23
Journal	Multiscale Modeling and Simulation
Volume	16
Issue number	1
DOIs	https://doi.org/10.1137/17M1141035
State	Published - 2018
Externally published	Yes

All Science Journal Classification (ASJC) codes

General Chemistry
Modeling and Simulation
Ecological Modeling
General Physics and Astronomy
Computer Science Applications

Keywords

Density of states
Electronic structure
Heterostructure
Momentum space
Two-dimensional materials

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10.1137/17M1141035

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author = "Daniel Massatt and Stephen Carr and Mitchell Luskin and Christoph Ortner",

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year = "2018",

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language = "English (US)",

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T1 - Incommensurate heterostructures in momentum space

AU - Massatt, Daniel

AU - Carr, Stephen

AU - Luskin, Mitchell

AU - Ortner, Christoph

PY - 2018

Y1 - 2018

N2 - To make the investigation of electronic structure of incommensurate heterostructures computationally tractable, effective alternatives to Bloch theory must be developed. In [Multiscale Model. Simul., 15(2017), pp. 476-499] we developed and analyzed a real space scheme that exploits spatial ergodicity and near-sightedness. In the present work, we present an analogous scheme formulated in momentum space, which we prove has significant computational advantages in specific incommensurate systems of physical interest, e.g., bilayers of a specified class of materials with small rotation angles. We use our theoretical analysis to obtain estimates for improved rates of convergence with respect to total CPU time for our momentum space method that are confirmed in computational experiments.

AB - To make the investigation of electronic structure of incommensurate heterostructures computationally tractable, effective alternatives to Bloch theory must be developed. In [Multiscale Model. Simul., 15(2017), pp. 476-499] we developed and analyzed a real space scheme that exploits spatial ergodicity and near-sightedness. In the present work, we present an analogous scheme formulated in momentum space, which we prove has significant computational advantages in specific incommensurate systems of physical interest, e.g., bilayers of a specified class of materials with small rotation angles. We use our theoretical analysis to obtain estimates for improved rates of convergence with respect to total CPU time for our momentum space method that are confirmed in computational experiments.

KW - Density of states

KW - Electronic structure

KW - Heterostructure

KW - Momentum space

KW - Two-dimensional materials

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DO - 10.1137/17M1141035

M3 - Article

AN - SCOPUS:85045054014

SN - 1540-3459

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EP - 451

JO - Multiscale Modeling and Simulation

JF - Multiscale Modeling and Simulation

IS - 1

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Incommensurate heterostructures in momentum space

Abstract

All Science Journal Classification (ASJC) codes

Keywords

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